Production and Testing of t he DØ Silicon Microstrip Tracker

1. Production and Testing of the DØ Silicon Microstrip Tracker Frank Filthaut University of Nijmegen / NIKHEF For the DØ Collaboration NSS-MIC, 15-20 October 2000 • The DØ Run II upgrade • The Silicon Microstrip Tracker design • Detector production • Testing • Expected performance • Conclusions

2. DØ Run II Upgrade • Bunch spacing: from 3.5 s to 132 ns (start @396 ns) • Aim: collect  2-3 fb-1 in several years • #MB interactions/crossing: 2-5 (@ 2-5 ·1032 cm-2 s-1) • Interaction region: z = 25 cm • Addition of central axial 2T magnetic field (SC solenoid in front of calorimeter cryostat) • Extend muon chamber coverage, smaller granularity (better lepton ID) • Upgraded calorimeter, trigger, DAQ electronics

3. DØ Run II Upgrade - Tracking Silicon Microstrip Tracker Fiber Tracker Forward Preshower Solenoid Central Preshower • B-tagging based on b lifetime (scintillating fibre tracker complemented by silicon strip detector) • Improved muon and electron (preshower detectors) identification and triggering • Charge sign determination • High-pT central physics in dense environment  redundancy • B physics, QCD studies  good forward coverage Physics requirements impacting tracker design: All these detectors use the SVX2 digital front-end chip

4. SMT Design 12 11 10 9 6 5 4 4 3 2 3 1 2 1 8 7 6 5 Barrels F-Disks H-Disks Layers/planes 4 12 4 Readout 12.4 cm 7.5 cm 14.6 cm Length Inner Radius 2.7 cm 2.6 cm 9.5 cm Outer Radius 9.4 cm 10.5 cm 26 cm Basic SMT Design: • 6 barrels • 12 F disks • 4 H disks Totals: 793k channels, 768 modules 3.0 m2 (of which 1.6 m2 DS) 1.5 M wire bonds • Axial strips to be used in L2 Silicon Track Trigger (STT): • stringent requirements on barrel alignment • six-fold azimuthal symmetry Should be radiation-hard to several Mrad (from pp interactions)

5. SMT Design SMT barrel cross-section: • Layers 1 (3): 12 (24) DS, DM 90º ladders produced from 6” wafers (6 chips) (barrels 1 & 6: SS axial ladders from 4” wafers: 3 chips) • Layers 2 (4): 12 (24) DS 2º ladders produced from 4” wafers (9 chips) Ladder count: 72 SS + 144 DS (90º) + 216 DS (2º) SMT disks: • F disks: 12 DS ±15º wedges (8+6 chips) • H disks: 96 SS 7.5º half-wedges made into full wedges and glued back to back (2x6 chips) Wedge count: 144 F + 96 H

6. Anatomy of a Ladder • Ladders supported by “active” (cooled) and “passive” beryllium bulkheads • Ladders fixed by engaging precision notches in beryllium substrates on posts on bulkheads • Beryllium cools electronics • expect chips to operate at 25 ºC using 70% H2O/30% ethyl glycol mixture at –10 ºC • hottest Si point should be at 5-10 ºC (DS), 0 ºC (SS) • High Density Interconnect (HDI) tail routed out radially between outer layers • Carbon-fibre/Rohacell rails glued to sensors for structural stiffness

7. High Density Interconnect • Two-layer flex-circuit mounted directly on silicon, housing SVX chips as well as passive electronics • Kapton based, trace pitch 200 m • Connects to “low-mass” cable using Hirose connector • 9 different types for the 5 sensor types • 2 for each sensor type except H disks • 2 types for each ladder differ only in tail length • Laminated to beryllium substrate (total mass  0.041 X0, of which 0.014 X0 from Si) Need 912 HDI’s 9-chip HDI H-wedge HDI

8. Ladder Production in steps (9-chip) 0. HDI laminated to beryllium substrates, all chips & passive components mounted and tested 1. Apply pattern of non-conductive epoxy on p-side beryllium 2. Align beryllium with respect to active sensor, apply pressure and cure for 24 hr 3. Align active & passive sensors w.r.t. each other, apply wire bonds. Then use separate fixture to position carbon-fibre rails. Use conductive epoxy to ground “passive” beryllium. Cure for 24 hr

9. Ladder Production in steps (9-chip) 4. Use “flip fixture” to have n-side on top 5. Apply epoxy to n-side beryllium, fold over and secure HDI. Apply pressure and cure for 24 hr. Then apply n-side Si-Si and Si-SVX wirebonds 6. Encapsulate bonds at HDI edges. Connect “active” beryllium to cable ground

10. Testing & Repairs Bonds need to be plucked Bad ground connection DAQ run stand-alone from spreadsheet program (+ help from probe station, logic analyzer) to checkpedestals, (selective) test charge inject, sparsification • Broken capacitors: cause SVX front-end to saturate, tends to affect neighbouring channels as well  pluck corresponding bonds • Bad grounding of beryllium substrates causes large pedestal structures (bad for common threshold) as well as high noise  ensure RBe-gnd < 10 (in fact now better than 1) • Repair broken / wrong bonds • Replace chips / repair tails damaged during processing

11. Burn-in & Laser Tests Laser Dead Channel Burn-in Test: Long-term (72 hr, 30’ between runs) test of whole ladder/wedge (conditions close to those in experiment) Laser Test: • Energy just < Si bandgap (atten. length  400 m  test full sensor thickness) • Find dead & noisy channels • Determine initial operating voltages (from pulse height plateau, Ileak-V curve) x-y movable laser head

12. Sensors Double-sided, double-metal sensors: Sensor delivery from Micron has been slow (30% yield) mainly due to p-stop defects on mask (noise affecting  10-15 strips) Schedule problem Single-sided sensors: Sensor flatness marginal for trigger purposes (understood to be due to processing: generic) Module assembly modified to minimise problem

13. Micro-discharges Worry for DS sensors using integrated coupling capacitors: • Potential difference across coupling capacitor oxide layer  high fringe field at edge in silicon bulk (see KEK 93-129) • Above certain voltage, micro-discharges (avalanche breakdown) cause burst noise inhibiting operation • Correlates with sudden increase of leakage current • Sensitive to implant-metal alignment • Worst at junction side (n+ side after type inversion) • Potentially limiting factor for lifetime of detector Example for un-irradiated detector (bias on p+-side): p+ metal at ground p+ metal floating

14. Micro-discharges Test on irradiated DSDM detector: • Irradiated with neutrons, fluence  1014 cm-2 (corresponding to several fb-1 for innermost DØ silicon layer, type inverted) • Kept at room temperature for  4 months for accelerated reverse annealing Different curves correspond to different p+ bias (-HV) for same total bias p-side noise After type inversion, problem worst at n+ side n-side noise Noise for un-irradiated detectors  2 ADC counts Applying bias to both p+ and n+ sides, total bias limited to  120-130 V (aim to keep noise below 3 counts) Assuming a 20-30 V overbias to retain high charge collection efficiency on p+ side, this limits the maximum depletion voltage to  100 V good for  4 fb-1

15. Production status and overall quality Production status: • All sensors delivered • All HDIs delivered • Ladder and wedge production, testing essentially complete (driven by HDI/sensor delivery) Detector classification: • Dead channel: laser response < 40 ADC counts • Noisy channel: (burn-in) pedestal width > 6 ADC counts(normally < 2 counts excluding coherent noise) • Grade A: less than 2.6% dead/noisy channels • Grade B: less than 5.2% dead/noisy channels Use only detector grades A,B; mechanically OK Example for 9-chip detectors (better for other detector types): Dead Noisy

16. Barrel Assembly in steps • Rule of thumb: • Align to 20 m (trigger) • Survey to 5 m (offline) • Precisely machined bulkheads • Barrel assembly done inside out (protect wire bonds) 1. Insert individual ladders into rotating fixture using 3D movable table 2. Manually push notches against posts (all under CMM)

17. Barrel Assembly • Layer 4 glued to bulkheads (providing structural stiffness, holding passive BH) • Thermally conductive grease applied (active BH only) for other layers 3. Secure ladder using tapered pins First 4 barrels assembled( 4 weeks/barrel, excluding survey)

18. F-Disk Assembly z=0 H H L H L H L H H Vdepl M M L • F-disk assembly less critical (not included in trigger), nevertheless performed under CMM (5-10 m accuracy) • Quick process • After assembly, “central” F-disk cooling rings screwed onto active barrel bulkheads All disks are not created equally! Distribution of different quality devices over disks: H/M = Micron high/medium Vdepl, L = Eurisys low Vdepl Prefer high Vdepl now to reach micro-discharge limit later

19. Half-cylinder assembly “Mating” of central F disks to barrels: Disk lowered on support arm, cooling ring screwed onto barrel BH Accuracy ~ 75 m in transverse plane Central part of first half-cylinder Individual barrel-disk assemblies lowered into CF support trough

20. Half-cylinder assembly Installation of end disks: End disks assembled and lowered into support trough First half-cylinder complete on 28/9 Afterwards: put on top cover, cut HDI tails to length, connect to “low-mass” cables, verify cooling circuit, test… almost done

21. Readout Electronics HDI 3M Low Mass IB Optical Link 1Gb/s SEQ SEQ SEQ NRZ/ CLK platform 1 5 5 3 VBD 68k VME V R B VRB Controller L3 HOST Secondary Datapath Examine • For 5% occupancy, 1 kHz trigger rate: 1010 bits/s  need error rate  10-15 • Exercise readout system as much as possible before installation in experiment  10% system test using full readout chain(readout full F disk, barrel, barrel-disk assembly, H disk) • Complete readout chain (including L3 analysis, data storage) tested on several detectors Monitoring Control

22. Conclusions & lessons Good: • Huge effort: • large amount of silicon • stringent constraints (alignment, material budget) • many different parts (5 sensor types, 9 HDI types), … • Now nearing (successful) completion, confident that the whole detector will be in place by 1/3/2001 startup date (even if not all electronics might be) • Think this detector should last at least ~ 4 fb-1 But: • We know it will not last for all of the Tevatron Run II (current projections by beams division ~ 15 fb-1, rather than original estimate of 2 fb-1) • We’re thinking of our next detector! If we have the luxury to learn from our experience this time: • Abandon DS silicon sensors (radiation hardness) • Lower number of sensor/hybrid types • Attempt to automate production as much as possible We have an exciting time ahead of us!